JP2021175318A - Power supply circuit and electronic control device - Google Patents

Abstract

To stably supply an output voltage even when a load current changes suddenly.SOLUTION: In one aspect of the present invention, in a control circuit 102 of a switching regulator, a load rapid decrease detection comparator 34 is provided separately from an abnormality (overvoltage) detection comparator 28. A threshold value VB3 of the load rapid detection comparator is set at a level lower than a threshold value VB1 of an abnormality (overvoltage) detection level to suppress increase in an output voltage Vo by performing an off control of a main switch 25 before an increased output voltage reaches the abnormality (overvoltage) detection level.SELECTED DRAWING: Figure 1

Description

The present invention relates to a power supply circuit for monitoring the output voltage of a switching regulator and stably supplying the output voltage according to the monitoring result, and an electronic control device including the power supply circuit.

In recent years, in the field of car electronics, a large number of ECUs (Electronic Control Units) have been put into practical use for power trains, automatic driving, and the like. The ECU is equipped with a microcontroller (hereinafter, also abbreviated as "microcomputer") that is responsible for various controls, and a power supply circuit that is responsible for the power supply of the microcomputer. In this power supply circuit, a switching regulator that converts a DC voltage based on a battery power supply into a different DC voltage and outputs it is used.

In the microcomputer for the ECU, the absolute value of the current consumption increases as the control function increases, and the rate of change of the current consumption also increases by switching on / off of each function. Therefore, in the switching regulator, even if the current consumption of the microcomputer (load current of the switching regulator) suddenly changes, the fluctuation of the power supply voltage of the microcomputer (the fluctuation of the output voltage of the switching regulator) is within the allowable range of the microcomputer. You are asked to do that.

Furthermore, in order to improve safety, the switching regulator has a function to prevent the output voltage of the switching regulator from rising and greatly exceeding the allowable range of the power supply voltage of the microcomputer when the loop wire that feeds back the output voltage is broken. It is desirable to have.

Patent Document 1 discloses an example of a method for detecting an abnormality in the output voltage of a switching regulator.

Japanese Unexamined Patent Publication No. 2006-238608

By the way, when the load current suddenly decreases (referred to as "load sudden decrease"), the output voltage of the switching regulator may rise and the output voltage may exceed the allowable voltage range.

The technique described in Patent Document 1 is a mechanism for monitoring an output voltage and, when an overvoltage exceeding the threshold value of a comparator is detected, determines that it is abnormal and turns off (shuts down) the main switch. Since the main switch is stopped by the determination of the abnormality of the output voltage, it is considered that the switching regulator and the entire system shift to the state where the abnormality is detected. However, this technique has a problem in that the output voltage rises and an abnormality may be detected every time the load is suddenly reduced, and the power supply circuit operates stably.

From the above situation, it is an object of the present invention to provide a power supply circuit and an electronic control device that stably supplies an output voltage even when the load current suddenly changes.

In order to solve the above problems, the power supply circuit of one aspect of the present invention uses a switching regulator that converts an input DC voltage into a target DC voltage by a switching operation of the switching element and outputs the switching element to perform the switching operation of the switching element. It is a power supply circuit provided with a control circuit for controlling.
The above control circuit
A resistance voltage dividing circuit that divides the output voltage of the switching regulator by resistance division, an error detection circuit that generates an error signal between the divided voltage and the set reference voltage, and a switch current detection circuit that detects the current flowing through the switching element. A first comparator that compares the output of the error detection circuit and the output of the switch current detection circuit, a clock source that outputs a clock signal, and an on signal for on-controlling a switching element that starts from the clock signal. A switch signal generation circuit that generates an off signal for off-controlling a switching element starting from the output signal of the first comparator, and a second comparator that detects that the output voltage has risen above the second reference voltage. And a switching function for switching the generation of the on signal of the switch signal generation circuit based on the output signal of the second comparator.
Then, when the second comparator detects an increase in the output voltage, the switching function switches the generation of the on signal in the switch signal generation circuit and controls so that the switching element does not turn on.

According to at least one aspect of the present invention, the output voltage can be stably supplied even when the load current suddenly changes.
Issues, configurations and effects other than those described above will be clarified by the description of the following embodiments.

It is a figure which shows the example of the power supply circuit which used the switching regulator which concerns on 1st Embodiment of this invention. It is a timing chart which shows the state of the signal of each part in the power supply circuit which concerns on 1st Embodiment of this invention. It is a figure which shows the example of the power supply circuit which used the conventional switching regulator. It is a timing chart which shows the state of the signal of each part in the conventional power supply circuit. It is a figure which shows the example of the power supply circuit which used the switching regulator which concerns on 2nd Embodiment of this invention. It is a timing chart which shows the state of the signal of each part in the power supply circuit which concerns on 2nd Embodiment of this invention. It is a figure which shows the example of the power-source circuit using the switching regulator which concerns on 3rd Embodiment of this invention. It is a timing chart which shows the state of the signal of each part in the power supply circuit which concerns on 3rd Embodiment of this invention. It is a figure which shows the example of the power-source circuit using the switching regulator which concerns on 4th Embodiment of this invention. It is a timing chart which shows the state of the signal of each part in the power supply circuit which concerns on 4th Embodiment of this invention. It is a figure which shows the structural example of the electronic control apparatus provided with the power supply circuit according to any 1st to 4th Embodiment of this invention.

Hereinafter, examples of embodiments for carrying out the present invention will be described with reference to the accompanying drawings. In the present specification and the accompanying drawings, components having substantially the same function or configuration are designated by the same reference numerals, and duplicate description will be omitted.

<First Embodiment>
First, the power supply circuit according to the first embodiment of the present invention will be described with reference to FIGS. 1 and 2. The present invention relates to a switching regulator type DC / DC converter (hereinafter referred to as “switching regulator”), which includes a power supply circuit for stably supplying an output voltage when a load current suddenly changes, and an electron including the power supply circuit. It is a control device.

[Power supply circuit configuration]
FIG. 1 shows an example of a power supply circuit using the switching regulator according to the first embodiment. The power supply circuit 100 shown in FIG. 1 includes a control circuit 102.

The switching regulator of FIG. 1 is an example of a step-down asynchronous rectification type switching regulator, which converts a DC voltage based on a power supply 111 into a different DC voltage (output voltage Vo) and loads 115 (for example, an electronic control device). (ECU)). As the switching regulator, a step-down asynchronous rectification type is exemplified, but a switching regulator to which the present invention is applied such as a synchronous rectification type is not limited to this example.

In the switching regulator, one end of the main switch 25 is connected to the power supply 111 via an input terminal (not shown) and a signal line 7. The other end of the main switch 25 is connected to one end of the inductor 113 via the signal line 8, and the other end of the inductor 113 is connected to the load 115 via an output terminal (not shown). A switching element such as a power MOSFET is used for the main switch 25.

A diode 112 is connected between the connection midpoint between the other end of the main switch 25 and one end of the inductor 113 and the ground. Further, the capacitor 114 is connected between the connection midpoint between the other end of the inductor 113 and the output terminal and the ground. Further, a signal line 9 is connected between the connection midpoint between the other end of the inductor 113 and the output terminal and the feedback terminal T of the control circuit 102.

In the power supply circuit 100, a desired output voltage Vo is obtained at the output terminal (signal line 9) by controlling the main switch 25 of the switching regulator on / off by the control circuit 102.

The control circuit 102 includes a clock source 20, a logic AND circuit 21, an RS type flip-flop 22, a driver circuit 23, and a switch current detection circuit 24. The input terminal of the clock source 20 and the logical AND circuit 21 is the signal line 1, the output terminal of the logical AND circuit 21 and the S terminal (set terminal) of the RS type flip-flop 22 are the signal line 2, and the Q of the RS type flip-flop 22. The terminal (output terminal) and the input terminal of the driver circuit 23 are connected by a signal line 4, and the output terminal of the driver circuit 23 and the gate terminal of the main switch 25 are connected by a signal line 5. Further, the switch current detection circuit 24 detects the current (main switch current) flowing from the power supply 111 to the main switch 25, and outputs a detection signal corresponding to the switch current to the switch current detection comparator 26.

Further, the control circuit 102 includes a switch current detection comparator 26, an abnormality detection determination circuit 27, an abnormality (overvoltage) detection comparator 28, and a reference voltage source 29. In the switch current detection comparator 26, the detection signal of the switch current detection circuit 24 is input to the non-inverting input terminal (+) via the signal line 6, and the output signal of the error amplifier 31 is input to the inverting input terminal (+) via the signal line 13. -) Is entered. The output signal of the switch current detection comparator 26 is input to the R terminal (reset terminal) of the RS type flip-flop 22 via the signal line 3.

In the abnormality (overvoltage) detection comparator 28, the output voltage Vo of the switching regulator is input to the non-inverting input terminal (+) via the signal line 9 and the feedback terminal T, and the reference voltage VB1 of the reference voltage source 29 is input to the inverting input terminal (+). -) Is entered. The output signal of the abnormality (overvoltage) detection comparator 28 is input to the abnormality detection determination circuit 27 via the signal line 10. The abnormality detection determination circuit 27 determines whether or not there is an abnormality in the switching regulator from the output signal of the abnormality (overvoltage) detection comparator 28, and outputs a switching regulator stop signal when the switching regulator is abnormal. The switching regulator stop signal is transmitted into the power supply circuit 100.

Further, the control circuit 102 includes a resistor R1, a resistor R2, and an error detection circuit 30. A resistor R1 and a resistor R2 are connected in series between the signal line 9 (feedback terminal T) and the ground. The error detection circuit 30 includes, for example, an error amplifier 31 and a reference voltage source 32. In the error amplifier 31, the voltage obtained by dividing the output voltage Vo by the resistors R1 and R2 is input to the inverting input terminal (-) via the signal line 12, and the reference voltage VB2 of the reference voltage source 32 is the non-inverting input terminal ( Entered in +). The output signal of the error amplifier 31 is input to the inverting input terminal (−) of the switch current detection comparator 26 via the signal line 13. The error detection circuit 30 may be configured by using a well-known technique as long as it can average the error between the signal representing the state of the output voltage Vo (here, the voltage dividing voltage) and the reference voltage VB2.

Further, the control circuit 102 includes a load sudden decrease detection circuit 33 and a logic inverter circuit 36. The load sudden decrease detection circuit 33 includes, for example, a load sudden decrease detection comparator 34 and a reference voltage source 35. In the load reduction detection comparator 34, the output voltage Vo is input to the non-inverting input terminal (+) via the signal line 9 (feedback terminal T), and the reference voltage VB3 of the reference voltage source 35 is input to the inverting input terminal (-). Will be done. VB3 is set to a value smaller than VB1. The output signal of the load reduction detection comparator 34 is input to the logic inverter circuit 36 via the signal line 14. The logic inverter circuit 36 inputs an inverted signal obtained by inverting the output signal of the load reduction detection comparator 34 to the logic AND circuit 21 via the signal line 15. The load sudden decrease detection circuit 33 may be configured as long as it can detect an increase in the output voltage Vo (a sudden decrease in load), and can be configured by using a well-known technique.

The control circuit 102 is mounted on an IC chip. Further, the control circuit 102 and the main switch 25 may be mounted on the IC chip.

[Timing chart of each part]
FIG. 2 is a timing chart showing a signal state of each part in the power supply circuit 100 according to the first embodiment. This timing chart shows the state of the waveform of the signal obtained in the main signal line of FIG. In FIG. 2, the output load current, the output voltage Vo (signal line 9), the output of the clock source 20 (signal line 1), the output of the load sudden decrease detection comparator 34 (signal line 14), and the S terminal of the RS type flip flop 22 (signal line 14). Signal line 2), Q terminal of RS type flip flop 22 (signal line 4), R terminal of RS type flip flop 22 (signal line 3), output of error amplifier 31 (signal line 13), and main switch current detection (signal line 13). Each waveform of the signal line 6) is shown. In FIG. 2, the RS type flip-flop 22 is referred to as “flip-flop 22”.

Here, it is assumed that the transition is made from a state in which the load current of the switching regulator (current consumption of the load 115) is stable at a large level to a state in which the load current suddenly decreases and the load current is stable at a small level. doing.

(Load current is stable)
When the load current is stable at a large level, a clock signal having a switching frequency at regular intervals is input from the clock source 20 to the S terminal (signal line 2) of the RS type flip-flop 22 via the signal line 1. Then, a signal at the Hi level is output from the Q terminal (signal line 4) at the rising edge of the clock signal. The output signal of the RS type flip-flop 22 causes the driver circuit 23 to turn on the main switch 25 via the signal line 5.

The main switch 25 is turned on, the current flowing from the power supply 111 to the load 115 is monitored by the switch current detection circuit 24, and the result is output to the signal line 6 connected to the switch current detection comparator 26.

On the other hand, the output voltage Vo (signal line 9) that rises when the main switch 25 is turned on is divided by a resistor R1 and a resistor R2 connected in series with the feedback feedback terminal T, and the divided voltage is taken out from the signal line 12. Is done.

The error amplifier 31 averages the error between the voltage dividing voltage (signal line 12) and the reference voltage VB2, and outputs the error to the signal line 13 connected to the switch current detection comparator 26. When the voltage dividing voltage input to the inverting input terminal rises, the output of the error amplifier 31 decreases.

The switch current detection comparator 26 compares the signal of the signal line 13 with the signal of the signal line 6 described above. Then, when the signal level of the signal line 6 exceeds the signal level of the signal line 13, a reset signal is input from the switch current detection comparator 26 to the R terminal of the RS type flip-flop 22 via the signal line 3. The signal output from the Q terminal (signal line 4) of the RS type flip-flop 22 changes from the Hi level to the Low level, and the main switch 25 is turned off from the driver circuit 23 via the signal line 5.

By repeating the on / off operation of the main switch 25 for each switching frequency in this way, the desired output voltage Vo (signal line 9) set by the divided voltage of the resistors R1 and R2 and the reference voltage VB2 is set. Is obtained.

Further, in the control circuit 102, an abnormality (overvoltage) can be detected in case the output voltage Vo (signal line 9) becomes abnormally high. The abnormality (overvoltage) detection comparator 28 compares the signal of the signal line 9 with the reference voltage VB1, and when the reference voltage VB1 is exceeded, the output signal of the signal line 10 changes to the Hi level. The output signal of the abnormality (overvoltage) detection comparator 28 is input to the abnormality detection determination circuit 27 via the signal line 10. When the abnormality detection determination circuit 27 determines that the output voltage Vo is abnormal, the abnormality detection determination circuit 27 outputs a signal to the signal line 11 to stop the switching regulator.

If the output voltage Vo (signal line 9) does not rise sharply, the result (signal line 14) of comparing the output voltage Vo with the reference voltage VB3 by the load sudden decrease detection comparator 34 is the Low level. Therefore, since the signal inverted to the Hi level in the logic inverter circuit 36 is input to the logic AND circuit 21 via the signal line 15, the clock signal supplied to the RS type flip-flop 22 is not masked (original). The state is maintained).

(A state in which the load current drops sharply)
Next, the case where the load current suddenly decreases will be described. When the load current suddenly decreases (timing t0), the output voltage Vo (signal line 9) suddenly rises, and when the output voltage Vo exceeds the reference voltage VB3, the output (signal line 14) of the load sudden decrease detection comparator 34 starts from the Low level. It changes to Hi level (timing t1). As a result, the output (signal line 15) of the logic inverter circuit 36 changes from the Hi level to the Low level.

While the output voltage Vo (signal line 9) is high, the clock signal of the signal line 1 is masked, and the output (signal line 2) of the logic AND circuit 21 becomes the Low level. Since the main switch 25 is not turned on, it is possible to suppress an increase in the output voltage Vo (signal line 9) immediately after the load is suddenly reduced.

After that, when the output voltage Vo (signal line 9) gradually decreases and the output voltage Vo falls below the reference voltage VB3 (timing t2), the output (signal line 14) of the load sudden decrease detection comparator 34 changes from the Hi level to the Low level. Changes to. Then, the output (signal line 15) of the logic inverter circuit 36 changes from the Low level to the Hi level.

If the clock signal (signal line 1) is at Hi level at this timing (timing t3), the output (signal line 2) of the logical AND circuit 21 becomes Hi level. Then, since the S terminal of the RS type flip-flop 22 changes from the Low level to the Hi level, an ON signal is output to the main switch 25.

However, as the output voltage Vo (signal line 9) rises, the output (signal line 13) of the error amplifier 31 starts to gradually decrease, although it takes time to average, so the main switch 25 is turned on. The time is short, and the amount of increase in the output voltage Vo (signal line 9) is small.

When the output voltage Vo exceeds the reference voltage VB3 again (timing t4) due to the rise of the output voltage Vo again, the signal line 15 changes to the Low level. Therefore, in the logical AND circuit 21, the clock signal (signal line 1) is masked and the main switch 25 is not turned on. While repeating such an operation, the output voltage Vo (signal line 9) gradually decreases.

Finally, the feedback loop of the entire switching regulator balances the load current to a stable state at a small level, and stabilizes the output voltage Vo (signal line 9).

The reference voltage VB3 for detecting a sudden decrease in load is set to a voltage lower than the reference voltage VB1 for detecting an abnormality (overvoltage). Before the output voltage Vo, which rises due to a sudden load decrease, is detected as an abnormality (overvoltage), the load sudden decrease detection comparator 34 detects the sudden decrease in load and quickly turns off the main switch 25 to perform normal operation (abnormality detection). Can maintain the state (not done).

As described above, the power supply circuit (power supply circuit 100) of the first embodiment uses a switching regulator that converts an input DC voltage into a target DC voltage by the switching operation of the switching element (main switch 25) and outputs the power supply circuit. A control circuit (control circuit 102) for controlling the switching operation of the switching element is provided.
The above control circuit
A resistance voltage divider circuit (resistors R1 and R2) that divides the output voltage of the switching regulator by resistance division,
An error detection circuit (error detection circuit 30) that generates an error signal between the divided voltage and the set reference voltage, and
A switch current detection circuit (switch current detection circuit 24) that detects the current flowing through the switching element, and
A first comparator (switch current detection comparator 26) that compares the output of the error detection circuit with the output of the switch current detection circuit,
A clock source (clock source 20) that outputs a clock signal and
A switch signal generation circuit (RS type flip-flop) that generates an on signal for on-controlling a switching element starting from a clock signal and an off signal for off-controlling a switching element starting from the output signal of the first comparator. 22) and
A second comparator (load reduction detection comparator 34) that detects that the output voltage has risen above the second reference voltage (VB3), and
A switching function (logical AND circuit 21) for switching the generation of an on signal of the switch signal generation circuit based on the output signal of the second comparator is provided.
The switching function is configured so that when an increase in the output voltage is detected by the second comparator, the switch signal generation circuit switches the generation of the on signal and controls the switching element so that it does not turn on.

Further, in the power supply circuit (power supply circuit 100) of the first embodiment, the control circuit (control circuit 102) has a third reference voltage (VB1) set to a value higher than the second reference voltage (VB3). A third comparator (abnormal (overvoltage) detection comparator 28) that detects an abnormal rise in the output voltage exceeding the above, and an abnormality detection determination circuit (abnormality detection) that determines an abnormality in the output voltage based on the output signal of the third comparator. The determination circuit 27) is provided.
In the present embodiment, the second comparator (load sudden decrease detection comparator 34) detects that the output voltage has risen before the third comparator determines that the output voltage is abnormal, and the switching function (logical AND circuit). 21) controls the switching element so that it does not turn on.

As described above, in the first embodiment of the present invention, the output voltage Vo is increased by adding the load sudden decrease detection comparator 34 to the control circuit 102 of the switching regulator in addition to the abnormality (overvoltage) detection comparator 28. Improvements are being made to suppress.

For example, the threshold value of the load sudden decrease detection comparator is set to a level lower than the abnormal (overvoltage) detection level, and the main switch is turned off before the rising output voltage reaches the abnormal (overvoltage) detection level. In this way, the normal operation can be maintained by suppressing the increase in the output voltage Vo due to the sudden decrease in load before detecting the abnormal (overvoltage) level.
Further, since the output of the error amplifier 31 having a long determination time for averaging is not used for detecting the sudden decrease in load, the time until the main switch 25 is turned off is short, and it is possible to suppress the output voltage Vo from continuing to rise.

<Conventional power supply circuit>
Next, a power supply circuit using a conventional switching regulator will be described with reference to FIGS. 3 and 4.

[Power supply circuit configuration]
FIG. 3 shows an example of a power supply circuit using a conventional switching regulator. The power supply circuit 200 shown in FIG. 2 uses a switching regulator and includes a control circuit 202. The switching regulator is an example of a step-down asynchronous rectification type switching regulator. Compared with the switching regulator (FIG. 1) of the first embodiment, the conventional switching regulator has a circuit configuration (logic AND circuit 21, load sudden decrease detection comparator 34, reference voltage source (VB3), logic inverter) for detecting a sudden decrease in load. The configuration is such that the circuit 36 and the signal lines 2, 14, 15) are removed.

[Timing chart of each part]
FIG. 4 is a timing chart showing a signal state of each part in the conventional power supply circuit 200. This timing chart shows the state of the waveform of the signal obtained in the main signal line of FIG. In FIG. 4, the output load current, the output voltage Vo (signal line 9), the output of the clock source 20 (signal line 1), the S terminal of the RS type flip-flop 22 (signal line 1), and the Q terminal of the RS type flip-flop 22. (Signal line 4), R terminal (signal line 3) of RS type flip-flop 22, output of error amplifier 31 (signal line 13), and main switch current detection (signal line 6) are shown.

Here, as in the case of FIG. 2, the load current of the switching regulator (current consumption of the load 115) is stable at a large level, the load current is rapidly reduced, and the load current is stable at a small level. It is assumed that the state has transitioned to the state. The operation in the state where the load current is stable is the same as that of the first embodiment (FIGS. 1 and 2).

When the load current suddenly decreases from a large level to a small level (timing t0), the output voltage Vo (signal line 9) of the switching regulator rises sharply. Since the voltage (signal line 12) divided by the resistor R1 and the resistor R2 connected in series with the feedback terminal T (also the signal line 9) rises, the output (signal line 13) of the error amplifier 31 decreases. , It gradually decreases due to the averaging process.

The time until the signal level of the signal line 13 exceeds the signal level of the signal line 6 that rises when the main switch 25 is turned on is gradually shortened, and the time until the signal level of the switch current detection comparator 26 is determined is also gradually shortened. .. As a result, the time from the rising edge of the clock signal of the clock signal input to the S terminal of the RS type flip-flop 22 to the input of the reset signal to the R terminal is also shortened. Therefore, the time when the Q terminal (signal line 4) of the RS type flip-flop 22 is at the Hi level, that is, the on time of the main switch 25 becomes shorter.

The output (signal line 13) of the error amplifier 31 that has dropped too much due to the sudden rise in the output voltage Vo (signal line 9) starts to rise when the output voltage Vo (signal line 9) drops, and the feedback loop of the entire switching regulator As a result, the load current is balanced in a stable state at a small level, and the output voltage Vo (signal line 9) is stabilized.

In this conventional power supply circuit 200, even if the output voltage Vo (signal line 9) suddenly rises immediately after the load current suddenly decreases, the output voltage of the error amplifier 31 is increased due to the averaging process of the error amplifier 31. It takes time to reduce the level to the level corresponding to Vo. The on-time of the main switch 25 becomes shorter as the output of the error amplifier 31 decreases, but the output voltage Vo (signal line 9) is until the output of the error amplifier 31 decreases to a level corresponding to the output voltage Vo. , There was a problem that it continued to rise. When the abnormality (overvoltage) detection comparator 28 detects that the output voltage Vo (signal line 9) exceeds the reference voltage VB1, the abnormality detection determination circuit 27 outputs a switching regulator stop signal, and the output voltage Vo drops. ..

<Second embodiment>
Next, the power supply circuit according to the second embodiment of the present invention will be described with reference to FIGS. 5 and 6.

[Power supply circuit configuration]
FIG. 5 shows an example of a power supply circuit using the switching regulator according to the second embodiment. The power supply circuit 100A shown in FIG. 5 uses a switching regulator and includes a control circuit 102A.

The power supply circuit 100A (control circuit 102A) is provided with a D-type flip-flop 37 instead of the logical AND circuit 21 and the RS-type flip-flop 22 with respect to the power supply circuit 100 (FIG. 1) according to the first embodiment. The point is different. In the connection to the D-type flip-flop 37, the output terminal of the clock source 20 and the CK terminal (clock) are connected via the signal line 1, and the output terminal and the D terminal of the logic inverter circuit 36 are connected via the signal line 15. ing. Further, the output terminal of the switch current detection comparator 26 and the R terminal (reset) are connected via the signal line 3. Then, the Q terminal and the input terminal of the driver circuit 23 are connected via the signal line 4.

In the first embodiment, it is possible to suppress an increase in the output voltage Vo (signal line 9) due to a sudden load decrease, but the output voltage Vo decreases and the output of the load sudden decrease detection comparator 34 (signal line 14). The main switch 25 is turned on at the timing when the level changes from the Hi level to the Low level. Therefore, there is a problem that switching noise having a frequency different from the switching frequency is generated.

Therefore, in the second embodiment, the D-type flip-flop 37 is applied, and the control method is such that the main switch 25 is always turned on at the timing of the rising edge of the clock signal which is the switching frequency. Further, the switching function for switching the generation of the on signal of the switch signal generation circuit based on the output signal of the second comparator is configured to be controlled by the D terminal input signal level of the D type flip-flop 37.

[Timing chart of each part]
FIG. 6 is a timing chart showing a signal state of each part in the power supply circuit 100A according to the second embodiment. This timing chart shows the state of the waveform of the signal obtained on the main signal line of FIG.

In FIG. 6, the output load current, the output voltage Vo (signal line 9), the CK terminal of the D-type flip flop 37 (signal line 1), the output of the load sudden decrease detection comparator 34 (signal line 14), and the D-type flip flop 37. D terminal (signal line 15), Q terminal (signal line 4) of D-type flip flop 37, R terminal (signal line 3) of D-type flip flop 37, output of error amplifier 31 (signal line 13), and main switch. Each waveform of the current detection (signal line 6) is shown. In FIG. 6, the D-type flip-flop 37 is referred to as “flip-flop 37”.

Here, it is assumed that the transition is made from a state in which the load current of the switching regulator (current consumption of the load 115) is stable at a large level to a state in which the load current suddenly decreases and the load current is stable at a small level. doing.

(Load current is stable)
When the load current is stable at a large level, the output (signal line 14) of the load sudden decrease detection comparator 34 is at the Low level, the output of the logic inverter circuit 36 (signal line 15) is at the Hi level, and the D-type flip-flop. The D terminal of is Hi level. From the clock source 20, a clock signal having a switching frequency at regular intervals is input to the CK terminal (signal line 1) of the D-type flip-flop 37 via the signal line 1, and the clock is input from the Q terminal (signal line 4). A signal at the Hi level is output at the rising edge of the signal. The output signal of the D-type flip-flop 37 causes the driver circuit 23 to turn on the main switch 25 via the signal line 5.

The main switch 25 is turned on, the current flowing from the power supply 111 toward the load 115 is monitored by the switch current detection circuit 24, and the result is output to the signal line 6 connected to the switch current detection comparator 26.

On the other hand, the output voltage Vo (signal line 9) that rises when the main switch 25 is turned on is divided (signal line 12) by the resistor R1 and the resistor R2 connected in series with the feedback terminal T that returns.

The error amplifier 31 averages the error between the voltage dividing voltage (signal line 12) and the reference voltage VB2, and outputs the error to the signal line 13 connected to the switch current detection comparator 26.

The switch current detection comparator 26 compares the signal of the signal line 13 with the signal of the signal line 6 described above. Then, when the signal level of the signal line 6 exceeds the signal level of the signal line 13, a reset signal is input from the switch current detection comparator 26 to the R terminal of the D-type flip-flop 37 via the signal line 3. The signal output from the Q terminal (signal line 4) of the D-type flip-flop 37 changes from the Hi level to the Low level, and the main switch 25 is turned off from the driver circuit 23 via the signal line 5.

By repeating the on / off operation of the main switch 25 for each switching frequency in this way, the desired output voltage Vo (signal line 9) set by the divided voltage of the resistors R1 and R2 and the reference voltage VB2 is set. Is obtained.

(A state in which the load current drops sharply)
When the load current suddenly decreases (timing t0), the output voltage Vo (signal line 9) suddenly rises, and when the output voltage Vo exceeds the reference voltage VB3, the output (signal line 14) of the load sudden decrease detection comparator 34 starts from the Low level. It changes to the Hi level (timing t11). As a result, the output (signal line 15) of the logic inverter circuit 36 changes from the Hi level to the Low level.

Then, since the D terminal of the D-type flip-flop 37 becomes the Low level, the output signal of the Q terminal (signal line 4) remains at the Low level at the rising edge of the next clock signal (timing t12), and the main switch 25 Does not turn on. Therefore, it is possible to suppress an increase in the output voltage Vo (signal line 9) immediately after the load is suddenly reduced.

After that, when the output voltage Vo (signal line 9) gradually decreases and the output voltage Vo falls below the reference voltage VB3 (timing t13), the output (signal line 14) of the load sudden decrease detection comparator 34 changes from the Hi level to the Low level. The output (signal line 15) of the logic inverter circuit 36 changes from the Low level to the Hi level.

At this timing, the D terminal of the D-type flip-flop 37 changes to the Hi level, but the Q terminal (signal line 4) does not change to the Hi level, so the main switch 25 does not turn on.

At the rising edge of the next clock signal (timing t14), the Q terminal of the D-type flip-flop 37 changes to the Hi level, so the main switch 25 is turned on and the output voltage Vo (signal line 9) starts to rise again. ..

However, as the output voltage Vo (signal line 9) rises, the output (signal line 13) of the error amplifier 31 starts to gradually decrease, although it takes time to average, so the main switch 25 is turned on. The time is short, and the amount of increase in the output voltage Vo (signal line 9) is small.

When the output voltage Vo exceeds the reference voltage VB3 again (timing t15, t16) due to the re-rise of the output voltage Vo, the D terminal (signal line 15) of the D-type flip-flop 37 changes to the Low level. Therefore, the rising edge of the clock signal of the CK terminal (signal line 1) is masked by the D-type flip-flop 37, and the main switch 25 is not turned on. While repeating such an operation, the output voltage Vo (signal line 9) gradually decreases.

Finally, the feedback loop of the entire switching regulator balances the load current to a stable state at a small level, and stabilizes the output voltage Vo (signal line 9).

As described above, in the second embodiment of the present invention, by applying the D-type flip-flop, the timing of re-turning on the main switch 25, which is off-controlled based on the output of the load sudden decrease detection comparator 34, and the rising edge of the clock signal. Improvements are being made to align.
By aligning the rising edge of the clock signal with the switching frequency with the timing at which the main switch 25 is turned on, it is possible to suppress the diffusion of the frequency of the switching noise, which is noise to the outside.

As described above, in the power supply circuit (power supply circuit 100A) according to the second embodiment, the timing at which the switching element (main switch 25) is turned on is the rising edge (the falling edge is also possible) of the clock signal (signal line 1). The on-signal generation of the switch signal generation circuit (D-type flip-flop 37) is controlled so as to synchronize with.

<Third embodiment>
Next, the power supply circuit according to the third embodiment of the present invention will be described with reference to FIGS. 7 and 8. In the third embodiment, a light load detection function is added to the second embodiment (FIG. 5). The light load is a state in which the load current of the switching regulator is small and it is not necessary to turn on the main switch 25 for each switching frequency. If the main switch 25 is turned on for each switching frequency, the desired output voltage Vo cannot be obtained, and the output voltage Vo rises. Therefore, the present embodiment is equipped with a function of intermittently operating (thinning out) the on signal for the main switch 25.

[Power supply circuit configuration]
FIG. 7 shows an example of a power supply circuit using the switching regulator according to the third embodiment. The power supply circuit 100B shown in FIG. 7 uses a switching regulator and includes a control circuit 102B.

The power supply circuit 100B (control circuit 102B) is based on the power supply circuit 100A (FIG. 5) according to the second embodiment, and has a light load detection comparator 38, a reference voltage source 39 of a reference voltage VB4, and logic as a light load detection function. The inverter circuit 40, the logic OR circuit 41, and the signal lines 16 and 17 are added.

The non-inverting input terminal (+) of the light load detection comparator 38 is connected to the output terminal of the error amplifier 31 via the signal line 13, and the inverting input terminal (−) is connected to the reference voltage source 39. The output terminal on which the light load detection comparator 38 outputs a signal according to the load state is connected to the input terminal of the logic inverter circuit 40 via the signal line 16. The output terminal of the logic inverter circuit 40 is connected to one input terminal of the logic OR circuit 41 via a signal line 17. Further, the other input terminals of the logic OR circuit 41 are connected to the output terminals of the load reduction detection comparator 34 via the signal line 14. The output terminal of the logic OR circuit 41 is connected to the input terminal of the logic inverter circuit 36.

[Timing chart of each part]
FIG. 8 is a timing chart showing a signal state of each part in the power supply circuit 100B according to the third embodiment. This timing chart shows the state of the waveform of the signal obtained on the main signal line of FIG. 7.

In FIG. 8, the output load current, the output voltage Vo (signal line 9), the CK terminal of the D-type flip flop 37 (signal line 1), the output of the load sudden decrease detection comparator 34 (signal line 14), and the light load detection comparator 38. Output (signal line 16), D terminal (signal line 15) of D-type flip flop 37, Q terminal (signal line 4) of D-type flip flop 37, R terminal (signal line 3) of D-type flip flop 37, error Each waveform of the output (signal line 13) of the amplifier 31 and the main switch current detection (signal line 6) is shown.

Here, from the state in which the load current of the switching regulator (current consumption of the load 115) is stable at a large level to the state in which the load current drops sharply and the load current is stable at a small level recognized as a light load. , It is assumed that there is a transition. Since the operation when the load current is stable at a large level and the operation when the load current suddenly decreases are the same as in the case of the second embodiment described above, the description thereof will be omitted.

(A state in which the load current drops sharply)
Hereinafter, the operation in a stable state at a small level in which the load current is recognized as a light load will be described.
A signal (signal line 17) obtained by inverting the light load detection signal (signal line 16) output by the light load detection comparator 38 by the logic inverter circuit 40, and a load sudden change detection signal (signal line 14) output by the load sudden decrease detection comparator 34. Is input to the logic OR circuit 41. Then, the output of the logic OR circuit 41 is input to the D terminal (signal line 15) of the D-type flip-flop 37 via the logic inverter circuit 36. When the D terminal (signal line 15) is at the Low level (timing t12), the rising edge of the clock signal of the CK terminal (signal line 1) is masked by the D-type flip-flop 37, and the main switch 25 is not turned on. On the other hand, when the D terminal (signal line 15) is at the Hi level, the main switch 25 is turned on starting from the rising edge (timing t14) of the clock signal of the CK terminal (signal line 1).

The light load is identified by comparing the output (signal line 13) of the error amplifier 31 and the reference voltage VB4 with the light load detection comparator 38. In the light load state, if the output voltage Vo (signal line 9) rises too much, the output (signal line 13) of the error amplifier 31 drops. When the error detection signal (signal line 13) becomes smaller than the reference voltage VB4, the output (signal line 16) of the light load detection comparator 38 changes from the Hi level to the Low level (timing t21), and the light load state is determined. ..

At this time, the D terminal (signal line 15) of the D-type flip-flop 37 also changes from the Hi level to the Low level from the signal line 16 via the logic inverter circuit 40, the logic OR circuit 41, and the logic inverter circuit 36. Since the rising edge of the clock signal of the CK terminal (signal line 1) is masked, the main switch 25 is not turned on.

Since the main switch 25 is not turned on, the output voltage Vo (signal line 9) decreases, and the output of the error amplifier 31 increases. As a result, the output (signal line 16) of the light load detection comparator 38 changes from the Low level to the Hi level (timing t22), and the main switch 25 can be turned on at the rising edge (timing t23) of the next clock signal. ..

Then, when the error detection signal (signal line 13) becomes smaller than the reference voltage VB4 after the main switch 25 is turned on, the output (signal line 16) of the light load detection comparator 38 changes from the Hi level to the Low level (timing). t24), it is determined that the load is light. At this time, the D terminal (signal line 15) of the D-type flip-flop 37 also changes from the Hi level to the Low level. Since the rising edge of the clock signal of the CK terminal (signal line 1) is masked, the main switch 25 is not turned on. At the time of light load, the switching regulator (light load detection comparator 38, D-type flip-flop 37, main switch 25) repeats such an operation, and the output voltage Vo (signal line 9) becomes stable.

Therefore, in a state where the load current is stable at a small level that is identified as a light load, the main switch 25 of the switching regulator operates intermittently.

The threshold value for detecting a sudden decrease in load determined by the reference voltage VB3 is set to a value higher than the threshold value for detecting a light load determined by the output of the error amplifier 31 and the reference voltage VB4 so as not to affect the light load detection function. That is, each reference voltage has a relationship of VB1> VB3> VB4.

As described above, in the power supply circuit (power supply circuit 100B) according to the third embodiment, the control circuit (control circuit 102B) indicates that the load connected to the power supply circuit is a light load due to an increase in the output voltage Vo. A light load detection circuit (light load detection comparator 38, reference voltage source 39, logic inverter circuit 40, logic OR circuit 41) for determining based on the output of the error detection circuit (error detection circuit 30) is provided.
In the present embodiment, the switching function is based on the output signal of the light load detection circuit or the output signal of the second comparator (load sudden decrease detection comparator 34), and is based on the ON signal of the switch signal generation circuit (D-type flip flop 37). The generation is switched, and when an increase in the output voltage is detected by the second comparator, the on-signal generation is switched in the switch signal generation circuit to control the switching element so that it does not turn on.

As described above, in the third embodiment of the present invention, in the switching regulator provided with the light load detection function, the increase in the output voltage Vo due to the addition of the load sudden decrease detection comparator 34 is suppressed without impairing the light load detection function. Improvements are being made.

<Fourth Embodiment>
Next, the power supply circuit according to the fourth embodiment of the present invention will be described with reference to FIGS. 9 and 10. In the fourth embodiment, in the third embodiment (FIG. 7), a disconnection detection function is added to the feedback terminal T (signal line 9) on which the output voltage Vo (signal line 9) returns.

FIG. 9 shows an example of a power supply circuit using the switching regulator according to the fourth embodiment. The power supply circuit 100C shown in FIG. 9 uses a switching regulator and includes a control circuit 102C.

The power supply circuit 100C (control circuit 102C) connects a constant current circuit 42 to the feedback terminal T (signal line 9) as a disconnection detection function based on the power supply circuit 100B (FIG. 7) according to the third embodiment. The disconnection is assumed to be the disconnection of the signal line 9. Specifically, it is assumed that the load 115 to which the output voltage Vo is supplied and the feedback terminal T (signal line 9) to which the output voltage Vo returns are disconnected.

In the configuration of the third embodiment (FIG. 7), when this disconnection occurs, the voltage of the feedback terminal T (signal line 9) drops. Due to the characteristics of the feedback loop of the switching regulator, when the voltage (signal line 12) divided by resistance from the voltage of the feedback terminal T (signal line 9) becomes lower than the set reference voltage VB2, the main switch 25 is turned on. It works in the direction. Since the output voltage Vo supplied to the load 115 deviates from the desired voltage and rises to the voltage of the power supply 111, a function to prevent it is required.

When this disconnection occurs, if the voltage (signal line 12) divided by resistance from the voltage of the feedback terminal T (signal line 9) can be set to a voltage higher than the set reference voltage VB2, the main switch 25 is turned off. It can be operated in the direction of making it. Therefore, in the present embodiment, a constant current circuit 42 for increasing the voltage of the feedback terminal T (signal line 9) after disconnection is provided.

[Timing chart of each part]
FIG. 10 is a timing chart showing a signal state of each part in the power supply circuit according to the fourth embodiment. This timing chart shows the state of the waveform of the signal obtained on the main signal line of FIG. 7.

In FIG. 10, the output voltage Vo (signal line 9), the CK terminal of the D-type flip flop 37 (signal line 1), the output of the load sudden decrease detection comparator 34 (signal line 14), and the output of the abnormality (overvoltage) detection comparator 28 (signal line 14). Signal line 10), stop signal of switching regulator (signal line 11), output of light load detection comparator 38 (signal line 16), D terminal of D-type flip flop 37 (signal line 15), Q of D-type flip flop 37 The waveforms of the terminal (signal line 4), the R terminal (signal line 3) of the D-type flip flop 37, the output of the error amplifier 31 (signal line 13), and the main switch current detection (signal line 6) are shown.

When the disconnection occurs (timing t30), the voltage of the feedback terminal T (signal line 9) rises due to the current supplied from the constant current circuit 42. The voltage rise of the feedback terminal T (signal line 9) can be detected by any of the abnormality (overvoltage) detection function, the load sudden decrease detection function, and the light load detection function, but the signal detected by the load sudden decrease detection comparator 34 is The main switch 25 can be turned off most quickly (timing t31).

Since the reference voltage VB1 which is the threshold value of the abnormality (overvoltage) detection comparator 28 is higher than the reference voltage VB3 which is the threshold value of the load sudden decrease detection comparator 34, the voltage of the feedback terminal T (signal line 9) rises to the reference voltage VB1. Judgment is delayed until (timing t32). Further, the internal delay of the abnormality detection determination circuit 27 further slows down the determination. Further, in the light load detection comparator 38, the determination is delayed because it takes time for the output of the error amplifier 31 for averaging the errors to decrease.

As described above, in the power supply circuit (power supply circuit 100C) according to the fourth embodiment, the control circuit (control circuit 102C) has a feedback terminal (T) in which the output voltage Vo is fed back to the resistance voltage dividing circuits (resistors R1 and R2). ) Is connected to a constant current circuit (constant current circuit 42) through which a constant current flows.
Then, when the connection (signal line 9) between the feedback terminal and the load of the switching regulator is broken, the second comparator (load sudden decrease detection) indicates that the voltage of the feedback terminal has increased due to the constant current of the constant current circuit. Detected by the comparator 34), the switching function switches the generation of the on signal of the switch signal generation circuit (D-type flip flop 37) and controls so that the switching element does not turn on.

As described above, the fourth embodiment of the present invention has a function of detecting disconnection (signal line 9) between the load 115 to which the output voltage Vo is supplied and the feedback terminal T to which the output voltage Vo returns. It is equipped with a switching regulator. By adding the load reduction detection comparator 34, the switching regulator has been improved so that it operates quickly from the detection of disconnection to the off control of the main switch 25.
That is, by using the load sudden reduction detection comparator 34 for determining the disconnection detection of the feedback terminal T, it is possible to quickly turn off the main switch 25.

<Fifth Embodiment>
Next, as a fifth embodiment of the present invention, an electronic control device including the power supply circuit according to any one of the first to fourth embodiments described above will be described with reference to FIG.

FIG. 11 shows a configuration example of an electronic control device including the power supply circuit according to any one of the first to fourth embodiments. Specifically, for example, the electronic control device is an in-vehicle ECU (Electronic Control Unit).

The vehicle control system includes a battery power supply 300 and an electronic control device 310. Inside the electronic control device 310, a power supply circuit 320 and a microcontroller (hereinafter abbreviated as "microcomputer") 330 are provided. A control circuit 322 is provided inside the power supply circuit 320. The power supply circuit 320 and the control circuit 322 correspond to any of the power supply circuits 100, 100A to 100C and the control circuits 102, 102A to 102C in the first to fourth embodiments described above, respectively.

The DC voltage of the battery power supply 300 is supplied to the power supply circuit 320 via the signal line 301, converted into a different DC voltage using the switching regulator, and supplied as the power supply voltage of the microcomputer 330 (load) via the signal line 304. Will be done. The microcomputer 330 is responsible for various controls of the vehicle by using the plurality of input signals 302 and the plurality of output signals 303.

The microcomputer 330 is becoming more sophisticated in order to support automatic operation and the like, and since there are many functions to control, the change in current consumption due to on / off switching of each function is large. The power supply circuit 320, which is responsible for the power supply of the microcomputer 330, is required to stably supply power to the microcomputer 330 even when the current consumption of the microcomputer 330 (load current of the power supply circuit 320) suddenly changes. That is, the fluctuation of the power supply voltage of the microcomputer 330 (the fluctuation of the output voltage Vo of the power supply circuit 320) needs to be kept within the permissible range of the microcomputer 330. Here, as means for suppressing an increase in the output voltage Vo of the power supply circuit 320 when the current consumption of the microcomputer 330 suddenly decreases, the power supply circuits 100, 100A to 100B of the first to third embodiments described above are described. Either can be applied.

Further, in order to improve safety, it has a function of preventing an increase in the output voltage Vo of the switching regulator when the feedback loop wire that feeds back the output voltage of the switching regulator is broken. As a result, it is possible to avoid a situation in which the power supply voltage Vo supplied to the microcomputer 330 rises too much and exceeds the maximum rating of the microcomputer 330. Here, as the disconnection detection function, the power supply circuit 100C of the fourth embodiment described above can be applied.

As described above, the first to fourth embodiments of the present invention are effective means for stabilizing the power supply and improving the safety of the electronic control unit (ECU).

Furthermore, the present invention is not limited to the above-described embodiments, and it goes without saying that various other application examples and modifications can be taken as long as the gist of the present invention described in the claims is not deviated. ..

For example, each of the above-described embodiments describes the configuration of a power supply circuit (switching regulator) in detail and concretely in order to explain the present invention in an easy-to-understand manner, and is not necessarily limited to those including all the components described above. .. In addition, it is possible to replace a part of the configuration of one embodiment with a component of another embodiment. It is also possible to add components of another embodiment to the configuration of one embodiment. It is also possible to add, replace, or delete other components with respect to a part of the components of each embodiment.

Further, each of the above configurations, functions, processing units and the like may be realized by hardware by designing a part or all of them by, for example, an integrated circuit. As hardware, FPGA (Field Programmable Gate Array), ASIC (Application Specific Integrated Circuit), or the like may be used. When it is performed by software, for example, a CPU or other arithmetic processing unit provided in the power supply circuit reads out a computer program stored in a recording medium such as a ROM provided inside the power supply circuit and executes it sequentially. You may be asked.

1 to 17 ... signal line, 20 ... clock source, 21 ... logic AND circuit, 22 ... RS type flip flop, 23 ... driver circuit, 24 ... switch current detection circuit, 25 ... main switch, 26 ... switch current detection comparator, 27 … Abnormality detection judgment circuit, 28… Abnormality (overvoltage) detection comparator, 29… Reference voltage source (VB1), 30… Error amplification circuit, 31… Error amplifier, 32… Reference voltage source (VB2), 33… Load sudden decrease detection circuit , 34 ... Load sudden decrease detection comparator, 35 ... Reference voltage source (VB3), 36 ... Logic inverter circuit, 37 ... D-type flip flop, 38 ... Light load detection comparator, 39 ... Reference voltage VB4, 40 ... Logic inverter circuit, 41 … Logic OR circuit, 42… constant current circuit, 100, 100A-100C… power supply circuit, 102, 102A-102C… control circuit, 111… power supply, 112… diode, 113… inductor, 114… capacitor, 115… load, 300 ... Battery power supply, 310 ... Electronic control device (ECU), 320 ... Power supply circuit, 322 ... Control circuit, 330 ... Microcontroller, 301-204 ... Signal line, R1, R2 ... Resistance, Vo ... Output voltage, VB1 to VB3 ... Reference voltage

Claims (7)

In a power supply circuit provided with a control circuit that controls the switching operation of the switching element by using a switching regulator that converts the input DC voltage into a target DC voltage by the switching operation of the switching element and outputs it.
The control circuit
A resistance voltage divider circuit that divides the output voltage of the switching regulator by resistance division,
An error detection circuit that generates an error signal between the divided voltage and the set reference voltage,
A switch current detection circuit that detects the current flowing through the switching element, and
A first comparator that compares the output of the error detection circuit with the output of the switch current detection circuit,
A clock source that outputs a clock signal and
An on-signal for on-controlling the switching element starting from the clock signal and a switch signal generation circuit for generating an off signal for off-controlling the switching element starting from the output signal of the first comparator. ,
A second comparator that detects that the output voltage has risen above the second reference voltage, and
A switching function for switching the generation of an on signal of the switch signal generation circuit based on the output signal of the second comparator is provided.
The switching function is a power supply circuit that switches the generation of the on signal in the switch signal generation circuit and controls the switching element so that the switching element does not turn on when the rise in the output voltage is detected by the second comparator. The control circuit
A light load detection circuit for determining that the load connected to the power supply circuit is a light load based on the output of the error detection circuit due to an increase in the output voltage is provided.
The switching function
When the on-signal generation of the switch signal generation circuit is switched based on the output signal of the light load detection circuit or the output signal of the second comparator, and an increase in the output voltage is detected by the second comparator. The power supply circuit according to claim 1, wherein the switch signal generation circuit switches the generation of the on signal and controls the switching element so that the switching element does not turn on. The control circuit
A third comparator that detects an abnormal rise in the output voltage that exceeds the third reference voltage set to a value higher than the second reference voltage, and
An abnormality detection determination circuit that determines an abnormality in the output voltage based on the output signal of the third comparator is provided.
A claim in which the second comparator detects that the output voltage has risen before the third comparator determines that the output voltage is abnormal, and the switching function controls the switching element so that it does not turn on. Item 2. The power supply circuit according to item 2. The control circuit
A constant current circuit that allows a constant current to flow is connected to the feedback terminal where the output voltage returns to the resistance voltage divider circuit.
When the connection between the feedback terminal and the load of the switching regulator is broken, the second comparator detects that the voltage of the feedback terminal has increased due to the constant current of the constant current circuit, and the switching is performed. The power supply circuit according to claim 3, wherein the switching element is controlled so as not to be turned on by a function. The switching function controls the generation of an on signal of the switch signal generation circuit so that the timing at which the switching element is turned on is synchronized with the rising edge or the falling edge of the clock signal. The power supply circuit described in item 1. The switch signal generation circuit is a D-type flip-flop.
The power supply circuit according to claim 5, wherein the switching function controls the generation of an on signal of the switch signal generation circuit at the D terminal input signal level of the D-type flip-flop. An electronic control device including a power supply circuit that generates an output voltage and a microcontroller that operates using the output voltage of the power supply circuit as a power supply.
The power supply circuit
Using a switching regulator that converts the input DC voltage to the target DC voltage by the switching operation of the switching element and outputs it,
It has a control circuit that controls the switching operation of the switching element.
The control circuit
A resistance voltage divider circuit that divides the output voltage of the switching regulator by resistance division,
An error detection circuit that generates an error signal between the divided voltage and the set reference voltage,
A switch current detection circuit that detects the current flowing through the switching element, and
A first comparator that compares the output of the error detection circuit with the output of the switch current detection circuit,
A clock source that outputs a clock signal and
An on-signal for on-controlling the switching element starting from the clock signal and a switch signal generation circuit for generating an off signal for off-controlling the switching element starting from the output signal of the first comparator. ,
A second comparator that detects that the output voltage has risen above the second reference voltage, and
A switching function for switching the generation of an on signal of the switch signal generation circuit based on the output signal of the second comparator is provided.
When the second comparator detects an increase in the output voltage, the switching function switches the generation of the on signal of the switching element in the switch signal generation circuit to control the switching element so that the switching element does not turn on. Control device.

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